CN100566323C - Be used for reducing the amplitude predistortion relevant of communication network parasitic emission with frequency - Google Patents
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L27/00—Modulated-carrier systems
- H04L27/32—Carrier systems characterised by combinations of two or more of the types covered by groups H04L27/02, H04L27/10, H04L27/18 or H04L27/26
- H04L27/34—Amplitude- and phase-modulated carrier systems, e.g. quadrature-amplitude modulated carrier systems
- H04L27/36—Modulator circuits; Transmitter circuits
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L27/00—Modulated-carrier systems
- H04L27/32—Carrier systems characterised by combinations of two or more of the types covered by groups H04L27/02, H04L27/10, H04L27/18 or H04L27/26
- H04L27/34—Amplitude- and phase-modulated carrier systems, e.g. quadrature-amplitude modulated carrier systems
- H04L27/36—Modulator circuits; Transmitter circuits
- H04L27/366—Arrangements for compensating undesirable properties of the transmission path between the modulator and the demodulator
- H04L27/367—Arrangements for compensating undesirable properties of the transmission path between the modulator and the demodulator using predistortion
- H04L27/368—Arrangements for compensating undesirable properties of the transmission path between the modulator and the demodulator using predistortion adaptive predistortion
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- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
- H03F—AMPLIFIERS
- H03F1/00—Details of amplifiers with only discharge tubes, only semiconductor devices or only unspecified devices as amplifying elements
- H03F1/32—Modifications of amplifiers to reduce non-linear distortion
-
- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
- H03F—AMPLIFIERS
- H03F1/00—Details of amplifiers with only discharge tubes, only semiconductor devices or only unspecified devices as amplifying elements
- H03F1/32—Modifications of amplifiers to reduce non-linear distortion
- H03F1/3241—Modifications of amplifiers to reduce non-linear distortion using predistortion circuits
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- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
- H03F—AMPLIFIERS
- H03F1/00—Details of amplifiers with only discharge tubes, only semiconductor devices or only unspecified devices as amplifying elements
- H03F1/32—Modifications of amplifiers to reduce non-linear distortion
- H03F1/3241—Modifications of amplifiers to reduce non-linear distortion using predistortion circuits
- H03F1/3247—Modifications of amplifiers to reduce non-linear distortion using predistortion circuits using feedback acting on predistortion circuits
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- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
- H03F—AMPLIFIERS
- H03F1/00—Details of amplifiers with only discharge tubes, only semiconductor devices or only unspecified devices as amplifying elements
- H03F1/32—Modifications of amplifiers to reduce non-linear distortion
- H03F1/3241—Modifications of amplifiers to reduce non-linear distortion using predistortion circuits
- H03F1/3294—Acting on the real and imaginary components of the input signal
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L25/00—Baseband systems
- H04L25/02—Details ; arrangements for supplying electrical power along data transmission lines
- H04L25/03—Shaping networks in transmitter or receiver, e.g. adaptive shaping networks
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L25/00—Baseband systems
- H04L25/02—Details ; arrangements for supplying electrical power along data transmission lines
- H04L25/03—Shaping networks in transmitter or receiver, e.g. adaptive shaping networks
- H04L25/03828—Arrangements for spectral shaping; Arrangements for providing signals with specified spectral properties
- H04L25/03834—Arrangements for spectral shaping; Arrangements for providing signals with specified spectral properties using pulse shaping
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- H—ELECTRICITY
- H03—ELECTRONIC CIRCUITRY
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- H03F2200/00—Indexing scheme relating to amplifiers
- H03F2200/102—A non-specified detector of a signal envelope being used in an amplifying circuit
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Abstract
---and preferably phase place---is that the predistortion relevant with frequency is added on the input signal amplitude, so that reduce because the parasitic emission that the later amplification of signal causes.In a preferred embodiment, pre-distortion technology of the present invention be with at U.S. Patent application No.09/395, (with frequency-independent) amplitude and the phase predistortion technology described in 490 (" ' 490 ' application ") are effective combinedly, wherein relevant predistortion with frequency corresponding to have be proportional to the amplitude of the frequency shift (FS) of carrier frequency and arbitrary limit of carrier frequency ± amplifier distortion of 90 ° phase shift.Because these characteristics are matched with those characteristics of differentiator, can reach the thorough correction of this part of amplifier distortion by using the differential filter circuit.Embodiments of the invention can be implemented in base band domain.The present embodiment can also be based on the look-up table that upgrades adaptively in time, to guarantee optimum performance.
Description
Technical field
The present invention relates to signal processing, particularly, relate to for example predistortion of the signal of the transmission in wireless communication networks, to reduce parasitic emission.
The cross reference of related application
That present patent application requires is that on March 8th, 2002 submitted to, temporary patent application number is 60/362,660, agent docket is the application of C0009PROV; Submitted on March 25th, 2002, temporary patent application number is 60/367,399, agent docket is the application of C0011PROV, and the rights and interests of the applying date of application that submit to, that Application No. is 10/153,446, agent docket is C0009 on May 22nd, 2002.That subject of this patent application relates to is that submit to (a) on September 14th, 1999, Application No. is 09/395,490, agent docket is the application (" ' 490 ' application ") of Johnson 6-1-17, (b) submitted on February 5th, 2002, Application No. is 10/068,343, agent docket is the application of C0001, (c) submitted on May 22nd, 2002, Application No. is 10/153,289, agent docket is the theme of C0011, and it is all instructed and is hereby incorporated by.
Background technology
The Modern wireless communication net adopts complicated modulation scheme, and it must strictly control parasitic emission (being sometimes referred to as " the outer emission of band "), to avoid interference adjacent carrier wave and to defer to regulations entity (for example FCC) and (for example, requirement ITU) of standard entity.A source of parasitic emission is the base station transmitter amplifier, and it is used in signal and sends to such as amplifying signal before wireless (for example, moving) unit of the wireless communication networks of cellular voice and/or data network as wireless (for example radio frequency) signal.The technology that being used to of prior art reduces such parasitic emission can satisfy former requirement.Yet nearest exploitation (for example, universal mobile telecommunications service (UMTS)) adds extra burden for the base station transmitter amplifier in the wireless communication networks, and this makes that it is favourable further reducing parasitic emission.
Summary of the invention
Embodiments of the invention are at the technology that the wireless communication networks parasitic emission is reduced to the level that satisfies current requirement.Particularly, embodiments of the invention comprise its amplitude---and preferably phase place---is the predistortion relevant with frequency, this predistortion is added on the input signal, to generate the signal of predistortion, when this pre-distorted signals is added to amplifier, cause parasitic emission lower in the amplifying signal that finally obtains.
In one embodiment, the present invention is the method that is used for reducing in the parasitic emission of amplifying signal, and method may further comprise the steps: (a) receiving inputted signal; Be amplitude that the predistortion relevant with frequency is applied on the input signal (b), to generate pre-distorted signals, like this, when pre-distorted signals was added to amplifier generation amplifying signal, this predistortion reduced the parasitic emission in amplifying signal.
Description of drawings
From following detailed description, appended claim and accompanying drawing, other purpose of the present invention, feature and advantage will be clear more fully, and wherein identical label is represented similar or identical unit.
Fig. 1 shows the block diagram according to the system of (with frequency-independent) pre-distortion technology of describing in the u.s. patent application serial number 09/395,490;
The block diagram of the digital predistorter of Fig. 2 displayed map 1;
The block diagram of the exemplary FPGA embodiment of the index of Fig. 3 displayed map 2 (index) computing module, time delay module, look-up table and output module;
The exemplary single channel of the receiver of Fig. 4 displayed map 1, the monotropic block diagram that changes embodiment;
Fig. 5 shows that have amplitude and phase place is the predistorter of the components for predistortion relevant with frequency and the block diagram of possible base band domain embodiment description, that combine with the components for predistortion of frequency-independent in ' 490 applications;
Fig. 5 A shows the block diagram of the hardware embodiment that is similar to Fig. 5, except the order of complex multiplication and differentiation step on secondary signal processing path is put upside down;
Fig. 6 shows the impulse response of linear amplitude filter of the difference filter of the predistorter be used for Fig. 5;
Fig. 7 shows the impulse response of Hilbert (Hilbert) transformed filter of the difference filter of the predistorter be used for Fig. 5;
Fig. 8 shows the impulse response of scalar filter scheme of the difference filter of the predistorter be used for Fig. 5;
Fig. 9 shows to have the block diagram that amplitude and phase place are the predistorter of the components for predistortion relevant with frequency and a possible RF territory embodiment combining with the components for predistortion of frequency-independent; And
Fig. 9 A shows the block diagram of the hardware embodiment that is similar to Fig. 9, except the order of complex multiplication and differentiation step on secondary signal processing path is put upside down.
Embodiment
The technology that reduces parasitic emission by the digital pre-distortion that uses enough satisfied regulations that existed in the past and standard is described in ' 490 applications.According to ' 490 applications, be amplitude and phase place that the predistortion relevant with frequency is added on the input signal, to generate the signal of (master) predistortion, when the signal of predistortion was exaggerated the device amplification later on, this pre-distorted signals reduced parasitic emission.According to embodiments of the invention, amplitude---and preferably phase place---be the predistortion relevant with frequency be added to additional (promptly, less important) on the pre-distorted signals, when the signal of the main predistortion that this pre-distorted signals is described is combined, can further reduce the parasitic emission in amplifying signal in applying for ' 490.Following part is provided at the explanation of the pre-distortion technology of instruction in ' 490 applications.It then is the explanation of the different possible implementation of components for predistortion, the amplitude of components for predistortion is relevant with frequency with phase place, components for predistortion preferably with but must with ' 490 the application pre-distortion technologies not combined, further to reduce the parasitic emission in the wireless network.
The pre-distortion technology of ' 490 applications
The pre-distortion technology of describing in ' 490 applications reduces channel power adjacent in wireless communication networks.Particularly, ' 490 applications are described and to be used for digitally and the technology of the predistortion signal of going out adaptively, this involves at signal and is added to, for example, apply correction for signal before the base station transmitter amplifier, like this, correction is to equate with the distortion of some expection at least that is produced by amplifier but direction is opposite.Proofread and correct and make that some amplifier distortion is offseted at least, cause base station transmitter to have more linear transmission characteristic compared with the corresponding transmitter that does not have such predistortion.Under these environment, adjacent channel power (level, parasitic emission) is reduced by hope ground.
Fig. 1 shows the block diagram according to the system 10 of the pre-distortion technology of describing in ' 490 applications.System 10 comprises digital predistorter 12, is used to receive the homophase (I) and quadrature (Q) component of the digital baseband signal of input; IQ modulator 14 is connected to the output of predistorter 12; Amplifier 16 is connected to the output of modulator 14; And receiver 18, be coupled to the output of amplifier 16 by coupler 17, so that generate the control signal that feeds back to predistorter 12.These parts be configured to correction be applied to generate by communication equipment (such as the base station that is used to send wireless communication data) and as input signal (I, Q) the input digit baseband signal that is added to predistorter 12 (for example, code division multiple access (CDMA) signal, the wideband CDMA signal, time division multiple access (TDMA) signal, the global system for mobile communications of passing through of the data rate that strengthens is assessed (EDGE) signal, or other signals, preferably has very big peak power to average power ratio).System 10 also provides the self adaptation feedback by receiver 18, makes to proofread and correct optimization.
More specifically, this pre-distortion technology is included in signal and correction is added to digital baseband signal before being added to the input of amplifier 16, is that at least a portion with the distortion that is produced by amplifier 16 is opposite so that proofread and correct.Therefore, correction mutually offsets with some part of amplifier distortion, causes system to have linear more transmission characteristic.In system 10, for accuracy and the low cost of utilizing digital circuit, digital predistorter 12 is preferably carried out its correction in base band, and the modulated device 14 of signal is transformed into radio frequency (RF) afterwards, so that amplify and transmission.
According to this pre-distortion technology, the amplitude and the phase place of predistorter 12 predistorted input signals are as the function of signal power (but with frequency-independent ground).Because amplitude and phasing change with signal power (that is, envelope power), predistorter 12 depends on the amplifier amplitude and phase place is carried out its function with the accurate explanation of the variation of power level.As will be described below, the function expression of proofreading and correct (to power level) has polynomial form, and preferably draws look-up table thus.
More specifically, digital baseband signal is made up of the discrete time sample of homophase (I) and quadrature (Q) component, and they are added to vector IQ modulator 14 behind the digital-analog conversion (not shown), and to generate the RF signal, this RF signal is imported into amplifier 16 then.Each sample of baseband signal can be expressed as (I+jQ) by complex representation, and wherein j is the square root of (1).The predistortion operation of predistorter 12 can be represented by following formula (1)-(3):
I′+jQ′=(I+jQ)(A+jB) (1)
Wherein
I′=IA-QB (2)
Q′=QA+IB (3)
Wherein I ' and Q ' by predistorter 12 generate, the homophase and the digital orthogonal baseband signal of predistortion, and A and B be pre-distortion parameters, they are functions of the instantaneous envelope power of the input signal represented by I and Q.Easily, can be stored in look-up table (it generates as described below) for the different numerical value of parameter A and B, index is by (I
2+ Q
2) instantaneous envelope power that provides.
Fig. 2 shows the block diagram according to the digital predistorter 12 pre-distortion technology, Fig. 1 of ' 490 applications.As shown in Figure 2, predistorter 12 comprises equalization filter 20, is used to receive signal aforesaid, that be made up of homophase and quadrature component.Equalization filter is the technical parts of knowing, and is used for being connected to amplitude limit module 22, and it arrives predetermined threshold value to signal wave elimination.The output of amplitude limit module 22 is fed to low pass filter 24, to eliminate the high fdrequency component that generates during slicing.
The output of low pass filter 24 is fed to sampling module 26, it (for example provides the up-sampling signal, increase by four times of sampling rates, be increased to 8X speed from original 2X speed) give Index for Calculation module 28, it is according to the homophase of baseband signal and the quadratic sum gauge index value of quadrature component.Index for Calculation module 28 is connected to the wherein look-up table 30 of stored parameter A and B.According to exponential number search argument A that calculates and the numerical value of B.
The pre-distortion parameters A of look-up table 30 and B draw from one group of multinomial, and this group multinomial is similar to and is used for making the linearizing correction of amplifier characteristic very much.Because the plural character of the characteristic of amplifier (such as class AB amplifier), a pair of multinomial that is used for B parameter by use can obtain favourable result, and single multinomial is enough for parameter A.(, we can say the amplitude distortion of parameter A masking amplifier, and the distortion of B parameter phase calibration as approximate.) these multinomials can be according to (4)-(7) by being write out to as follows:
A=C
0+ C
1P+C
2P
2+ C
3P
3For A≤A
N1(4)
A=A
N1Otherwise (5)
B=C
4P+C
5P
2+ C
6P
3For P≤P
b(6)
B=(B
B1-B
B2)
1+ C
7P+C
8P
2+ C
9P
3For P>P
b(7)
P=(I wherein
2+ Q
2) be instantaneous envelope power.A
mBe the maximum that is added to parameter A, saturated to prevent that amplifier is driven into by the degree of depth.The representative value of Am is 2, but it can change with detailed design.P
bIt is the bending point of B parameter transition between formula (6) and (7) wherein.P
bIt is the optimized parameter that obtains by optimized algorithm.This number changes with different amplifiers.It also can vary with temperature.Bb1 and Bb2 be that formula (6) and (7) obtains by using respectively, at P=P
bThe time B parameter numerical value.First on formula (7) right side trends towards making formula (6) and (7) at P=P
bThe place continuously.C
0To C
9Be coefficient, and they change with wearing out of temperature, amplifier or the like about the transfer function of specific amplifier.As P
bThe same, optimized algorithm find out provide the optimization result, coefficient C
0To C
9Numerical value.
Certainly, should see that under suitable situation, two multinomials can be used in parameter A and B parameter.And, under many situations, might reduce formula (4) and (6), get rid of the item of the linear term that is higher than P, cause following formula (4 ')-(7 '):
A=C
0+ C
1P is for P≤P
b(4)
A=(A
B1-A
B2)+C
2P+C
3P
2+ C
4P
3For P>P
b(5)
B=C
5P is for P≤P
b(6)
B=(B
B1-B
B2)+C
6P+C
7P
2+ C
8P
3For P>Pb (7)
A wherein
B1And A
B2Be respectively by use that formula (4 ') and (5 ') obtains at P=P
bThe time parameter A numerical value.Just as before, greatest limit A can be set for the numerical value of parameter A
mIn addition, if necessary, carry out the breakover point P of transition from a polynomial equation to another polynomial equation
bCan for the A equation with have different numerical value for the B equation.
In order to be adapted to coefficient (for example, the C in formula (4)-(7)
0-C
9) time variation matter, in this pre-distortion technology, adopt adaptation scheme, thus, coefficient value is the parasitic emission of optimization (or being applied) to keep minimum or to reduce at least off and on.Referring again to Fig. 1, in this output of coupler 17 samplings of the output of amplifier 16, and the receiver 18 that is tuned to frequency field that will be reduced or minimized parasitic emission generates the voltage that is proportional to received power.A plurality of receivers can be used in more than one frequency sampling parasitic emission, or single receiver sequentially be tuned to different interested frequencies.The voltage that obtains at different frequency places is combined into single amount then, and its numerical value is will be reduced or minimized.When using two frequencies (this is normally enough), the voltage V that finally obtains
1And V
2Can be combined into as follows according to formula (8):
V=V
1+V
2+|(V
1-V
2)| (8)
Wherein | (V
1-V
2) | be (V
1-V
2) absolute value.Such use of absolute value makes V
1And V
2Be reduced or be minimized, rather than these two numerical value only are provided and value.If only use two of the right side of formula (8), then algorithm can voltage be very little and another is quite big by making one, and may find pseudo-best.The alternative of formula (8) is V=max (V
1, V
2), wherein the max meaning is to select the greater of two numerical value.
Find out and reduce or minimize V, thereby the suitable algorithm of numerical value that reduces the coefficient of parasitic emission is to be existed by Nelder and Mead " A Simplex Method for FunctionMinimization (the simple method that is used for function minimization) ", Computer Journal, Vol.7, simple algorithm that describe, that know among the pp.308-313 (1965), this article is quoted at this, for your guidance.As what describe below, algorithm is implemented with the form of revising.
Referring again to Fig. 2, according to the feedback signal from the receiver of Fig. 1, the simple algorithm that processing module 32 implements to revise upgrades the parameter A that is stored in the look-up table 30 and the numerical value of B.Should see that processing module 32 can be got the such various forms of treatment circuit such as microprocessor, digital signal processor or use FPGA device.Should see that also this simple algorithm can be implemented in any suitable mode of the suitable combination that utilizes hardware and software, these modes will be appreciated that after those skilled in the art read this paper.Certainly, the device (being module 32 here) that is used for implementing algorithm should comprise suitable storage capability, is used for storage and maintenance for operation necessary code of algorithm and data.
When each iteration, the numerical value of the coefficient that is drawn by algorithm is used for generating form at the above-mentioned formula that is used for A and B, and this form is made by algorithm and is used for being used for next iteration.Algorithm is allowed to continuous operation, or operation at least off and on, and like this, coefficient value is followed the tracks of the change that takes place in time.
Plan to be used for the functional value that minimizes or reduce to obtain by the simple optimized algorithm of Nelder and Mead exploitation by mathematical computations.The important aspect of this operational mode is, repeats if calculate, and then obtains identical functional value.This with by for the numerical value that measures of operation hardware in pairs than, noise and rise and fall and to cause changing the value of measurement inevitably wherein.When attempting for the simple algorithm of the real-time use of the hardware of operation, this difference has important result.
The essence of simple algorithm is, when each iteration, the coefficient sets relevant with the worst functional value is presented one group of new replacement of better functional value.It is possible or not necessarily better that this new numeric ratio plays the best functional value that obtains before this time, but along with the algorithm progress, the functional value that expection will obtain becoming better and better.Suppose, because noise or fluctuating in measuring obtains good especially but vicious numerical value.If the numerical value that obtains later on all is worse compared with this wrong numerical value, then algorithm will be converged on this improper value.Therefore, with its habitual form, algorithm is not to be suitable for very much being used in the situation that has sizable fluctuating when quantity is optimized or carries out computing by present situation.
In order to overcome this difficulty, simple algorithm is used with the form of revising.At the end of each iteration, if in the past best numerical value is replaced by better numerical value, then algorithm enters next iteration.Yet if iteration does not produce new best value, existing last point is reappraised and new numerical value replaces numerical value in the past.Therefore, algorithm can recover because the data of the mistake that the measurement that rises and falls causes.These fluctuatings can cause the iteration of bigger number, so that reach the point of wanting (this can be an optimum), do not reach the point of wanting but do not stop.
Another correction of simple algorithm make it can Continuous Tracking because the change of the amplifier characteristic that temperature change, part aging or other disturbances cause.In traditional embodiment of algorithm, set up withdraw from criterion (criterion be usually directed to this simple worst point and the most better between the part of functional value change) and when satisfy this criterion algorithm terminate.When reach want or during optimum, algorithm reduces this simple size, it typically became very little before the time that reaches the point of wanting.In case this situation takes place, algorithm just no longer can be reacted for the change of amplifier characteristic.
In a preferred embodiment, by when each iteration begins simple size with compare such as the such numerical value of the minimum value that sets in advance, if and simple size is reduced to and is lower than this numerical value, then increase size to this numerical value, and stop this simple size to become too little.This numerical value is selected as making it enough big, makes the change that algorithm can the follower amplifier characteristic, but is unlikely to too big and can not reaches (or best) point of wanting.Suitable value is that to differ at the value of this each coefficient of simple worst point place and the most corresponding numerical value at better place be 5 to 10% place.
Continuation is with reference to Fig. 2, the output of sampling module 26 also is connected to delay circuit 34, this delay circuit is connected to output module 36 again, and output module is according to generating output signal from the numerical value of the parameter A of look-up table 30 retrieval and B and up-sampling signal from the time-delay of delay circuit 34.The time-delay that is applied by delay circuit 34 preferably is equivalent to the time-delay that comprises in Executive Module 28 and 30, like this, (I and Q) reaches output module 36 simultaneously with the suitable numerical value of (A and B).
The block diagram of the exemplary FPGA embodiment 300 of the Index for Calculation module 28 of Fig. 3 displayed map 2, delayer 34, look-up table 30 and output module 36.I and Q data path carry out square independently at multiplier 302 and 304 respectively, produce I
2And Q
2These two numerical value are added together in adder block 206, are formed for the index address of look-up table, and look-up table is got two two-port RAM memory blocks 308 that separate and 310 form on Fig. 3, and these two memory blocks comprise parameter A and B respectively.Multiplier 312,314,316 and 318, multiply by the I and the Q value of time-delay from the parameter of memory block output, produce four values I * A, I * B, Q * A, Q * B.These four values are by adder and subtractor block 320 and 322 combinations, form (IA-QB) and (QA+IB) respectively, and they are output as I ' and Q '.
Have sufficiently high processing speed in for example processing module and obtain under the situation of A and B parameter with the principle that allows basis " on demand ", the look-up table configuration is unnecessary.In this case, processing module is calculated suitable coefficient, and need not be stored in look-up table to such parameter on demand or by being calculated by processing module after A and the B parameter with wanting.
Referring again to Fig. 1, the receiver 17 in the digital predistortion adaptation feedback loop is used for measuring the RF power on the narrow-band of specific frequency.This tuning frequency for example departs from main CDMA carrier frequency and is the frequency of the parasitic emission that will reduce by optimized algorithm.
The exemplary single channel of the receiver 18 of Fig. 4 displayed map 1, the monotropic block diagram that changes embodiment.In this embodiment, receiver 18 comprises frequency synthesizer 50, and it is connected to frequency mixer 52.The output of frequency mixer 52 is connected to low pass filter 54, and this low pass filter is connected to intermediate frequency (IF) chain 56 again.The output of IF chain 56 is connected to analog-to-digital converter (ADC) 58, and it provides the processing module 32 that is input to Fig. 2 then.Three important frequencies of Fig. 4 are RF frequencies, measure adjacent power level on this frequency; Local oscillator (LO) frequency, it changes on demand, with tuned receiver; And intermediate frequency (IF), it is fixed.The LO frequency can be found by LO=RF=IF.
More specifically, as shown in the figure, the RF input of receiver 18 provides coupler 17 to be coupled to the output of power amplifier 16.This broadband RF signal is down converted to intermediate frequency (IF), wherein IF=RF-LO in frequency mixer 52.The LO frequency that is used for frequency mixer 52 is generated by phase-locked loop (PLL) frequency synthesizer 50.This LO frequency is by (numeral) tune command setting from microprocessor (for example, the processing module 32 of Fig. 2).
In certain embodiments, optimized algorithm monitors the parasitic emission on a plurality of Frequency points, and in this case, the single channel receiver of Fig. 4 can retune for each different frequency.This retuning by being similar to following program process finished:
Microprocessor (for example, processing module 32) sends tune command to frequency synthesizer, be provided with the LO frequency (from but the tuning frequency of receiver).
Microprocessor waits for that PLL and RSSI set.
Digitized RSSI value is read by microprocessor.If use average RSSI, can get a plurality of readings.
Repeat these steps for next frequency.
The pre-distortion technologies of ' 490 applications are designed to amplitude (mainly obtaining by parameter A) and the phase place (main operation parameter B obtains) by the predistortion baseband signal, and masking amplifier some is non-linear at least.Yet, (peak power approaches 1 to the ratio of average power in the characteristic of signal, as in the single channel tdma system) do not allow enlarging amplitude greatly, so that under the situation that the amplitude non-linearity of amplifier can not be corrected fully application is arranged as wanting.In using, these, can obtain very big improvement by phase calibration (via B parameter) as much as possible with by correction amplitude in Am numerical part ground suitably is set.
Amplitude relevant and phase predistortion with frequency
As what describe in last joint, the pre-distortion technologies of ' 490 applications can be used for reaching very big the reducing of parasitic emission, but often see and still have some remaining parasitic emission.Attempt to reduce these remaining parasitic emission by the coefficient in the correction formula (4) to (7) (formula (4 ') is to (7 ')), cause asymmetric situation, wherein reduce to follow increase with in the front end parasitic emission of communication channel in the low frequency end parasitic emission of communication channel, or vice versa, causes deterioration total on the performance (or not having total improvement at least).
According to embodiments of the invention, in order to reduce parasitic emission to (with the frequency-independent) level that pre-distortion technology reaches that is lower than by ' 490 applications, the amplitude that applies is the predistortion relevant with frequency with phase place.
The distortion that is caused by amplifier can be looked at as by two parts to be formed.First, being that irrelevant and ' 490 applications (with other traditional and pre-distortion technology frequency-independent) solve with signal bandwidth, is relevant with the curvature of the amplifier transfer function of the distortion that causes AM-AM (amplitude is to amplitude) and AM-PM (amplitude is to phase place) type.The predistortion of ' 490 applications is by proofreading and correct the curvature distortion of this part of process amplifier effectively of transfer function.
The second portion of amplifier distortion is insignificant for narrow band signal, but it becomes more and more important when bandwidth increases.This part of amplifier distortion have be proportional to the amplitude of the frequency shift (FS) of carrier frequency and arbitrary limit of carrier frequency ± 90 ° phase shift.Because these characteristics are matched with those characteristics of differentiator, can reach the thorough correction of this part of amplifier distortion by using the differential filter circuit.
The combination of two corrections can be expressed as follows by formula (9):
Γ+jQ′=(I+jQ)(A+jB)+d{(I+jQ)(X+jY)}/dt (9)
Wherein I and Q are the homophase and the quadrature components of the input signal before predistortion, and I ' and Q ' they are the corresponding components after predistortion, and j is-1 square root, and A, B, and X and Y are pre-distortion parameters, they are instantaneous power P (P=I
2+ Q
2) function.Symbol d/dt representative is for the differential of time.First of the right side of formula (9) represents the irrelevant part of bandwidth of predistortion, and second representative depends on the part of bandwidth.Second can be extended to formula (10) as follows:
d{(I+jQ)(X+jY)}/dt=d(I
d+jQ
d)/dt=d(I
d)/dt+jd(Q
d)/dt,(10)
(I wherein
d+ jQ
d)=(I+jQ) (X+jY).And it is as follows that derivative can be approximately:
d(I
d)/dt≈δI
d/δt,d(Q
d)/dt≈δQ
d/δt (11)
Incremental time δ t is much smaller than the inverse of signal bandwidth.
Pre-distortion parameters A, B, X and Y, if want, can use polynomial repressentation according to following formula (12)-(15):
A=a
0+a
1P+a
2P
2+a
3P
3+... (12)
B=b
1P+b
2P
2+b
3P
3+... (13)
X=x
1P+x
2P
2+x
3P
3+... (14)
Y=y
1P+y
2P
2+y
3P
3+... (15)
Should be pointed out that the item that has nothing to do with P appears in the formula (12), but it does not appear in the formula (14).The item a that power is irrelevant
0Be in formula (12), because first the output on the right side of formula (9) (promptly, main pre-distorted signals) comprises original input signal and pre-distorted signals, a but similarly not appearance in formula (14), (that is, less important pre-distorted signals) only is pre-distorted signals because second the output on the right side of formula (9).
Amplitude and the phase predistortion relevant in the base band domain with frequency
Fig. 5 shows that amplitude and phase place are the less important components for predistortion relevant with frequency and the block diagram of combined hardware (for example, FPGA, ASIC, or the DSP) embodiment of the main pre-distorted signals that generates according to ' 490 applications.Particularly, the Index for Calculation module 28 of the predistorter 12 of Fig. 2, look-up table 30, delayer 34 and output module 36 are shown as first the output configuration of Fig. 5, that generate the right side of formula (9) (that is main pre-distorted signals I,
0, Q
0) part.In addition, on Fig. 5, look-up table 502 is preserved the numerical value of parameter X and Y, and they can be access in according to the index that is generated by module 28, made by complex multiplication module 504 and differential filter 506 then and be used for second output (that is less important pre-distorted signals I, on the right side of computing formula (9)
1, Q
1).
34 compensation of time-delay piece are calculated (I by module 28
2+ Q
2) numerical value and from look-up table 30 and 502 the retrieval A, B, needed time of the numerical value of X and Y.The output of module 36 piece 508 of being delayed time is further delayed time, and becomes output transform the less important needed time of pre-distorted signals (that is, to calculate I at formula (10) with compensation by differential filter 506
dAnd Q
dTime of time-derivative).Main pre-distorted signals (I
0, Q
0) then in combiner modules 510 with less important pre-distorted signals (I
1, Q
1) combined, with the pre-distorted signals that generates new combination (I ', Q '), they are modulated and be exaggerated (for example, by modulator 14 and the amplifier 16 of Fig. 1) then, so that send.
On Fig. 5, be used for A and B and be used for X and two groups of multinomial formula of Y (that is formula (12)-(15)) are shown as precalculated look-up table (that is, 30 and 502).In replacing embodiment, look-up table 30 and or look-up table 502 can be replaced according to the polynomial real-time calculating in formula (12)-(15).Under any situation, depend on application, " endless " multinomial can be by ignoring higher order term by approximate in formula (12)-(15).For example, in a preferred embodiment, formula (12) and (13) can be similar to by ignoring all items that are higher than three rank items, and formula (14) and (15) can quilt be approximate by ignoring all items that are higher than the single order item.As for the coefficient that is used for generating A and B, the coefficient that is used for generating X and Y can be by using simple algorithm to be generated and being upgraded adaptively.
Differentiating of filter 506 can be implemented in various modes.A method is to use according to difference following formula (16), between adjacent sample to be similar to this differential:
(δI
d)
n={(I
d)
n+1-(I
d)
n-1}/2,(δQ
d)
n={(Q
d)
n+1-(Q
d)
n-1}/2,(16)
The subscript of its bracket outside is meant catalogue number(Cat.No.).If sample frequency is much larger than signal bandwidth, then this being similar to is effective.The division that is divided by by δ t is unnecessary, because this division can be introduced zoom factor, it can be introduced in the multinomial of look-up table or X and Y.
[c
1,c
2,c
3]=[0.5,0,-0.5] (17)
Alternatively, the characteristic of differentiator, promptly, be proportional to from the amplitude of the frequency shift (FS) of carrier frequency and arbitrary limit of carrier frequency ± 90 ° phase shift, cascade that can be by two filters (promptly, tandem compound) is implemented, each filter is FIR or IIR (infinite impulse response) filter, one of them filter is the linear amplitude filter that has constant time-delay and be proportional to the amplitude response of frequency, and another filter is that (sign of coefficient is reversed hilbert-transform filter, so that it is consistent with the definition of differentiator), its amplitude response is constant with frequency, and its phase response all is 90 ° (except constant time-delays) in all frequencies.Fig. 6 and 7 shows each impulse response of linear amplitude FIR filter and Hilbert transform FIR filter respectively, and these two filters can be combined, and forms differential filter 506.Should be pointed out that the linear amplitude filter that differential filter 506 can be used in before or after the hilbert-transform filter implements.
In another possible embodiment, the characteristic of wanting can have some compromise single filter by use and obtain on the precision of linear amplitude and 90 ° of phase shifts.Fig. 8 shows the representative impulse response of single differential FIR filter.The sample frequency of this single filter can be, but needn't be far above signal bandwidth.
Use the filter coefficient of formula (17), cause under sample frequency is the condition of octuple signal bandwidth at least, producing superior result's simple proposal.Use the cascade of two filters, greater flexibility is provided, because in two filters can be customized to amplifier have nonlinear amplitude response and be not 90 ° or with the situation of the phase response of frequency change under (can not use hilbert-transform filter in this case), create the amplitude and the phase response that are matched with amplifier.
Fig. 5 A shows the block diagram of the hardware embodiment that is similar to Fig. 5, except the order of complex multiplication and differentiation step on secondary signal processing path is put upside down.Particularly, on Fig. 5 A, differential filter 506A is placed on the front of complex operation piece 504a.Carry out the needed time of differential in order to compensate, this embodiment comprises additional delay piece 512.Behind the order of the complex operation of given Fig. 5 A and differentiation step, the address pointer that points to look-up table 502a is contemplated to the (i that the numerical value i that generates by differential filter 506a and q draw
2+ q
2).In any case, be used for the address pointer (i of look-up table 502a by use
2+ q
2) can obtain enough good result, this pointer is generated by Index for Calculation module 28, avoids thus generating (i
2+ q
2) time extra computation that involves.
Amplitude and the phase predistortion relevant in the non-base band domain with frequency
It is that available situation is operated in base band domain that the embodiment of Fig. 5 and 5A is designed to for baseband signal I and Q.When baseband signal is can not provide the time, the input signal that predistortion is applied to such as the non-base band domain in RF territory or IF territory is favourable.Particularly, notice if time-delay much smaller than the inverse of signal bandwidth, time-derivative can be used in difference between the version of time-delay of waveform and waveform and come approximately according to following formula (18), differentiating of formula (10) can be in non-base band domain enforcement:
δ(I
d+jQ
d)
t={(I
d+jQ
d)
t+δ1-(I
d+jQ
d)
t-δt}/2, (18)
Wherein subscript is represented the time relationship of waveform.The division that is divided by by δ t is unnecessary, because this division can be introduced zoom factor, it can be introduced in the multinomial of look-up table or X and Y.
Fig. 9 shows the block diagram of the possible RF territory hardware embodiment of predistorter.Between the module in module in the RF of Fig. 9 embodiment and the base band embodiment of Fig. 5 total relation is one to one arranged.
Particularly, on Fig. 9, the RF input signal is split into two paths, and a paths enters envelope detector 902, and it produces the output signal of the instantaneous envelope power that is proportional to the RF input signal.(alternatively, the signal that is proportional to the instantaneous envelope power of RF input signal can be used in the situation of the suitable change of the numerical value of storing in the look-up table.) this signal is by ADC 906 digitlizations, the output of the numeral of ADC is used for obtaining pair of control signal value (for example, voltage V from look-up table 906
01And V
02).This is added to vector modulator 910 to control signal, and the function of vector modulator is amplitude and the phase place according to control signal modified R F signal.Second RF input signal path enters delay unit 908 (for example, the coaxial cable of a segment length), and it makes RF signal and control signal V
01And V
02Arrive vector modulator 910 simultaneously.Depend on embodiment, can, but not necessarily afford redress for the decay of delay unit 908.Vector modulator 910 is delayed time by delay unit 910, generates the I that is similar to Fig. 5
0, Q
0Main RF pre-distorted signals.
The output of ADC 904 is split into two digital signal path corresponding to look-up table 906 and 914, and the output of delay unit 908 is split into two RF signal paths corresponding to vector modulator 910 and 916.Look-up table 914, vector modulator 916 and differential circuit 918 provide the I that is similar to Fig. 5
1, Q
1Less important RF pre-distorted signals.Particularly, the item (I+jQ) on the right side of look-up table 914 and vector modulator 916 enforcement formula (9) (X+jY).
As shown in Figure 9, differential circuit 918 is by using splitter 922, delay unit 924, attenuator 926 and combiner 928 effective, they lump together by approximate (divided by 2 is unwanted, because the numerical value in the look-up table 914 can be by suitable adjusting) of using formula (18) and implement differentiating with respect to the time.Splitter 922 splits into two RF signal paths to the RF signal that is generated by vector modulator 916, one signal path is added to the delay unit 924 of time-delay RF signal, another paths is added to attenuator 926, and its decay RF signal is with the decay of compensation delay unit 924.Combiner 928 combinations generate less important pre-distorted signals from the RF signal of delay unit 924 and attenuator 926.Splitter 922 and combiner 928 are designed to apply 180 ° of rotations between two RF signals, so that always deduct the signal from the time-delay of delay unit 924 in the deamplification of self damping device 926.Such rotation can reach by using 90 ° of splitters and 90 ° of combiners.Alternatively, can use 0 ° of splitter and 180 ° of combiners, or vice versa, other suitable combinations of any splitter in back and combiner.
The time-delay of being introduced by delay unit 912 is half of the time-delay introduced by delay unit, therefore, the output of vector modulator 910 is placed on half the position of time between two signals of input end of combiner 928.Should be by the time-delay that delay unit 924 is introduced much smaller than the inverse of signal bandwidth.1/5th the numerical value that is equal to or less than the inverse of signal bandwidth provides superior result.
Combined by RF combiner 920 from the main pre-distorted signals of delay unit 912 with from the less important pre-distorted signals of combiner 928, wherein the signal of combination constitutes the predistortion RF output signal that is added to amplifier.
Because by predistortion, the modulator that is similar to the IQ modulator 14 of Fig. 1 can be omitted input signal in the RF territory in the RF of Fig. 9 embodiment.In other embodiments, wherein input signal by predistortion, needs frequency mixer that the IF signal transformation of the predistortion that finally obtains is become the RF territory at low frequency (for example, in the IF territory), after this just is added to amplifier.
In the embodiment depicted in fig. 9, X and Y are shown as and are implemented as look-up table after parameter A and the B.Alternatively, these parameters can be by calculating at the polynomial numerical value of formula (12) in (15), and by valuation.Under any situation, be used for generating A, B, the coefficient of X and Y can be by using simple algorithm to be generated and upgrading adaptively.
Fig. 9 A shows the block diagram of the hardware embodiment that is similar to Fig. 9, except the order of complex multiplication and differentiation step on secondary signal processing path is put upside down.Particularly, differential circuit 918a is placed on the front of vector modulator 916a.Carry out the time that differential needs in order to compensate, this embodiment comprises additional time-delay piece 930.Should be pointed out that in a preferred embodiment the exponential quantity that is generated by ADC 904 is used for from look-up table 914a access parameter V
11And V
12Numerical value.
Alternative embodiment
Depend on concrete application, Fig. 5,5A, 9 and 9A shown in configuration can be implemented aspect the circuit of the module that comprises the equalization filter 20, amplitude limit module 22, low pass filter 24 and the sampling module that are similar to Fig. 2.In replacement embodiment of the present invention, can omit one or more (with in addition all) these parts and maybe can comprise one or more other processing unit, depend on the requirement of the characteristic and the concrete communication network of input signal.
Describe though the present invention is (with frequency-independent) amplitude and the combined configuration aspect of phase predistortion that depends on Frequency and Amplitude and phase predistortion and ' 490 application of the present invention therein, the present invention is not limited to this.In this case, configuration shown in Figure 5 for example can be by omitting look-up table 30 and output module 36, and the copy of input signal from the time-delay of time-delay piece 34 directly is sent to time-delay piece 508, and keep handling look-up table 502 and module 504 simultaneously, and be corrected.
Also might implement the amplitude predistortion relevant and the unreal relevant phase predistortion of frequency of granting, have or do not have ' 490 applications and predistortion frequency-independent with frequency.In this case, configuration shown in Figure 5 for example can be modified into and make 506 in filter be implemented by the linear amplitude filter, as shown in Figure 6.
Though the present invention describes aspect the wireless signal of the one or more mobile units that send to wireless communication networks from the base station, the present invention is not limited to this.In theory, embodiments of the invention can be implemented for the wireless signal that sends to one or more base stations from mobile unit.The present invention also can be at other wireless and even wire net aspect be implemented, to reduce parasitic emission.
Embodiments of the invention may be implemented as the process based on circuit, are included in embodiment possible on the single integrated circuit.It will be appreciated that as those skilled in the art the various functions of circuit element may be implemented as the treatment step in the software program.Such software for example can be utilized in digital signal processor, microcontroller or all-purpose computer.
The present invention can be embodied as method and be used to put into practice the form of the equipment of these methods.The present invention also can be embodied as the form that goes up the program code that embodies at tangible medium (such as floppy disk, CDROM, hard disk drive or any other machine-readable storage medium), wherein, when program code is loaded onto when carrying out such as the machine of computer with by machine, machine becomes and is used to put into practice equipment of the present invention.The present invention for example also can be embodied as no matter be stored in medium, still be loaded in machine and or carried out by machine, still by some transmission medium or carrier, such as passing through cable or wire, by optical fiber, or the program code that is transmitted by electromagnetic radiation, wherein, when program code is loaded onto when carrying out such as the machine of computer with by machine, machine becomes and is used to put into practice equipment of the present invention.When being implemented on general processor, program code segments and processor are combined, so that the equipment of the uniqueness that is similar to specific logical circuit operation to be provided.
Should also be understood that those skilled in the art can make various changes under the condition that does not deviate from the scope of representing of the present invention in following claim in details, material and the arrangement of the parts of describing in order to explain character of the present invention and showing.
Claims (10)
1. method that is used for reducing the parasitic emission of amplifying signal may further comprise the steps:
(a) receiving inputted signal; With
(b) predistortion is applied to input signal, to generate the signal of predistortion, like this, when pre-distorted signals was added to amplifier with the generation amplifying signal, this predistortion reduced the parasitic emission in amplifying signal, and wherein step (b) may further comprise the steps:
(1) generates main pre-distorted signals from input signal;
(2) generate the amplitude less important pre-distorted signals relevant with frequency from input signal with phase place; With
(3) make up main pre-distorted signals and less important pre-distorted signals, to generate pre-distorted signals, wherein said less important pre-distorted signals has:
Be proportional to amplitude from the frequency offset of the carrier frequency of input signal;
The phase shift of spending in one side+90 of carrier frequency; With
Phase shift at the another side-90 of carrier frequency degree.
2. the process of claim 1 wherein:
Input signal is that baseband signal and predistortion are applied in base band domain.
3. the process of claim 1 wherein that step (b) (1) comprises is applied to input signal to amplitude with the phase place predistortion relevant with frequency, to generate the step of main pre-distorted signals.
4. the process of claim 1 wherein that less important pre-distorted signals is relevant with the bandwidth of input signal.
5. the process of claim 1 wherein that less important pre-distorted signals is based on the time diffusion of the signal that generates from input signal.
6. the method for claim 5, wherein time diffusion is applied to the signal that the complex multiplication by input signal generates.
7. the method for claim 5, wherein time diffusion was applied to input signal before the complex multiplication of the differential signal that finally obtains.
8. the process of claim 1 wherein what the predistortion relevant with frequency was based on from the look-up table data retrieved, wherein look-up table upgrades adaptively according to the control signal that generates according to amplifying signal.
9. equipment that is used for reducing the parasitic emission of amplifying signal, wherein this equipment comprises:
(a) main signal processing path is configured to generate main pre-distorted signals from input signal;
(b) less important signal processing path is configured to generate less important pre-distorted signals from input signal, and the amplitude of wherein less important pre-distorted signals is relevant with frequency with phase place; With
(c) combiner, be configured to make up main pre-distorted signals and less important pre-distorted signals, to generate pre-distorted signals, make, when pre-distorted signals is added to amplifier with the generation amplifying signal, this predistortion reduces the parasitic emission in amplifying signal, and wherein said less important pre-distorted signals has:
Be proportional to amplitude from the frequency offset of the carrier frequency of input signal;
The phase shift of spending in one side+90 of carrier frequency; With
Phase shift at the another side-90 of carrier frequency degree.
10. the equipment of claim 9, wherein said less important pre-distorted signals are based on the time diffusion of the signal that generates from input signal.
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US60/367,399 | 2002-03-25 | ||
US10/153,446 US7197085B1 (en) | 2002-03-08 | 2002-05-22 | Frequency-dependent magnitude pre-distortion for reducing spurious emissions in communication networks |
US10/153,446 | 2002-05-22 |
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KR (1) | KR100959032B1 (en) |
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Also Published As
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WO2003077496A1 (en) | 2003-09-18 |
CN1640086A (en) | 2005-07-13 |
US7197085B1 (en) | 2007-03-27 |
GB2401520A (en) | 2004-11-10 |
GB2401520B (en) | 2005-08-10 |
GB0418316D0 (en) | 2004-09-15 |
DE10392344T5 (en) | 2005-04-21 |
KR20040091706A (en) | 2004-10-28 |
KR100959032B1 (en) | 2010-05-20 |
AU2003213691A1 (en) | 2003-09-22 |
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